Events on January 25 in history

A 6.0 Richter scale earthquake hits western Colombia killing at least 1,000.

The Richter scale, originally known as the Richter magnitude scale or Richter's magnitude scale, was a groundbreaking measure of earthquake strength. It was conceptualized and introduced by American seismologist Charles Francis Richter in his seminal 1935 paper, where he initially termed it the "magnitude scale." This pioneering work laid the foundation for quantifying seismic events.

The initial Richter scale was specifically designed for local earthquakes in Southern California, using data from a particular type of seismograph (the Wood-Anderson seismograph). Over time, this original measure was refined and subsequently renamed the local magnitude scale, commonly denoted as M_L or M_L . Its development marked a significant step forward in seismology by providing a standardized way to compare earthquake sizes.

Despite its historical significance, the original M_L  scale had several limitations. For instance, it tended to "saturate" for very large earthquakes (typically above magnitude 7), meaning it couldn't accurately distinguish between the true sizes of extremely powerful events. Furthermore, its measurements were dependent on the type of instrumentation used and the distance from the earthquake's epicenter. Because of these and other shortcomings, most seismological authorities today primarily utilize more advanced and robust scales, such as the moment magnitude scale (M_w ), to report earthquake magnitudes.

However, it is a common practice in news media and public discourse to still refer to these reported magnitudes as "Richter" magnitudes, even when they are technically based on the moment magnitude scale or other modern derivatives. It's important to understand that all modern earthquake magnitude scales, including M_w , retain the fundamental logarithmic character introduced by Richter. This logarithmic scaling is crucial for making the vast range of earthquake energies manageable for measurement and comparison.

To illustrate the logarithmic nature: each whole number increase on the scale represents a tenfold increase in the amplitude of the seismic waves recorded by a seismograph. More profoundly, it signifies an approximate 32-fold increase in the energy released by the earthquake. For example, a magnitude 6 earthquake releases roughly 32 times more energy than a magnitude 5, and approximately 1,000 times more energy than a magnitude 4. This means a magnitude 3 quake effectively factors 10³ in amplitude relative to a baseline, while a magnitude 5 quake is 100 times stronger in wave amplitude than a magnitude 3, demonstrating how the logarithmic approach compresses a wide range of values into a more convenient scale.

Case Study: The 1999 Armenia, Colombia Earthquake

A tragic illustration of an earthquake's devastating power occurred on January 25, 1999, at 13:19 local time in Colombia. This significant seismic event, known as the 1999 Armenia, Colombia earthquake, had its epicenter located approximately 40 kilometers (25 mi) west-southwest of Ibagué, Colombia. It registered a magnitude of 6.2 on the moment magnitude scale (M_w ), making it the strongest earthquake to strike Colombia in 16 years.

The earthquake's shallow depth contributed significantly to its destructive impact. The shock heavily afflicted the city of Armenia, the capital of the Quindío department, which bore the brunt of the devastation. The tremors also severely impacted about 18 other towns and 28 additional villages situated within Colombia's vital Coffee-Growers Axis region, encompassing parts of the Quindío, Risaralda, and Caldas departments. To a lesser degree, but still significantly, the cities of Pereira and Manizales also experienced considerable damage.

The human and economic toll of the 1999 Armenia earthquake was immense. It claimed the lives of approximately 1,185 people, injured over 8,000, and left around 250,000 individuals homeless. The widespread destruction included the collapse of numerous buildings, severe damage to infrastructure, and a significant setback to the region's crucial coffee industry. This event underscored the critical importance of accurate earthquake measurement and preparedness in seismically active regions.

Frequently Asked Questions About Earthquake Magnitude

What is the primary difference between the Richter scale and the Moment Magnitude Scale (M_w )?

The original Richter scale (M_L ) measures the amplitude of seismic waves recorded on a specific type of seismograph and is primarily suitable for local, smaller earthquakes. The Moment Magnitude Scale (M_w ), now the global standard, measures the seismic moment, which is a more accurate and physically grounded measure of an earthquake's size based on the area of the fault rupture and the amount of slip. M_w  does not saturate for large earthquakes, making it reliable for events of all sizes.

Why do news reports often still refer to "Richter" magnitudes?

Despite scientists predominantly using M_w , the term "Richter scale" became deeply embedded in public consciousness and media lexicon following its introduction. It is often used as a generic term to refer to any earthquake magnitude, even when the underlying measurement is based on the more advanced moment magnitude scale.

What does the logarithmic nature of earthquake scales mean for understanding earthquake strength?

The logarithmic nature means that each whole number increase on the magnitude scale (e.g., from 5 to 6) represents a tenfold increase in the amplitude of the seismic waves measured and approximately 32 times more energy released by the earthquake. This dramatic increase in energy with each unit highlights why even small numerical differences in magnitude can correspond to vast differences in destructive potential.

Can a "negative" earthquake magnitude occur?

Yes, theoretically. Because the scale is logarithmic, very small seismic events, such as those caused by mining blasts or small collapses, can register with negative magnitudes. However, these are generally imperceptible to humans and typically only detectable by highly sensitive instruments.